Engineering:Star Bus
The Star Bus satellite platform is designed for various applications, including communications, remote sensing, and scientific missions. The highly configurable platform allows customization to meet specific mission requirements. In addition, it can support a wide range of payloads, including high-resolution imaging systems, microwave sensors, and advanced communication systems.
The Star Bus platform is designed with a modular architecture, allowing for easy integration of various subsystems and payloads. The bus provides power, communications, and data handling capabilities, while the loads provide mission-specific capabilities. The platform is designed to be highly reliable and has been used in various missions, including the Hubble Space Telescope and NASA's New Horizons mission to Pluto.
Evolution of the Star Bus Platform
Since its initial development, the Star Bus platform has undergone continuous enhancements, expanding its capabilities for increasingly complex missions. Orbital ATK, now part of Northrop Grumman after its acquisition in 2018, has further refined the platform to support geostationary communications satellites, low Earth orbit (LEO) missions, and interplanetary exploration. These advancements include improvements in power generation, thermal management, and propulsion systems, making it one of the most versatile satellite platforms in the industry. The Star Bus family has been employed in both commercial and governmental projects, including the SES and Intelsat communications constellations.[1][non-primary source needed]
History
Variants
| Name | Mission type | Orbit | Payload capability | Mission life | |||
|---|---|---|---|---|---|---|---|
| RapidStar-1 | Military/Reconnaissance | LEO | 60 kg/75W | 1–5 years | |||
| RapidStar-2 | Military/Reconnaissance | LEO | 200 kg/500W | 1–5 years | |||
| LEOStar-2 | Civil/Military | LEO | 150 kg/400W | 1–10 years | |||
| LEOStar-3[2] | Civil/Military | LEO | 3,000 kg/800W | 1–10 years | |||
| GEOStar-1 | Military/Reconnaissance | GEO | 150 kg/200W | 5–7 years | |||
| GEOStar-2 | Communications | GEO | 500 kg/5.5 kW | 15–18 years | |||
| GEOStar-3 | Communications | GEO | 800 kg/8.0 kW | 15–18 years | |||
| MicroStar-1 | Constellation | LEO | 15 kg/360W | 1–3 years | |||
| ESPAStar-1 | Military/Reconnaissance | LEO or GEO | 250 kg/500W | 1–5 years | |||
| ESPAStar-2 | Military/Reconnaissance | LEO or GEO | 1,080 kg/1.2 kW | 1–5 years | |||
| References: [3] | |||||||
See also
References
- ↑ "Northrop Grumman-built Commercial Telecommunications Satellites Launched Successfully" (in en). https://news.northropgrumman.com/news/releases/northrop-grumman-built-commercial-telecommunications-satellites-launched-successfully.
- ↑ LEOStar-3 Bus
- ↑ "Spacecraft Busses". Archived from the original on 6 September 2016. https://web.archive.org/web/20160906171929/http://www.orbitalatk.com/space-systems/spacecraft-buses/default.aspx. Retrieved 27 March 2016.
Further reading
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